Your search keyword '"Schipper PJ"' showing total 3 results

1. Impact of the HIV-1 genetic background and HIV-1 population size on the evolution of raltegravir resistance.

Author

Fun A, Leitner T, Vandekerckhove L, Däumer M, Thielen A, Buchholz B, Hoepelman AIM, Gisolf EH, Schipper PJ, Wensing AMJ, and Nijhuis M

Subjects

Amino Acid Substitution, Anti-HIV Agents pharmacology, Anti-HIV Agents therapeutic use, Biological Evolution, Cell Line, Drug Resistance, Viral drug effects, Genetic Background, HIV Infections virology, HIV Integrase genetics, HIV Integrase Inhibitors pharmacology, HIV Integrase Inhibitors therapeutic use, HIV-1 enzymology, High-Throughput Nucleotide Sequencing, Humans, Population Density, RNA, Viral blood, Selection, Genetic drug effects, Treatment Failure, Drug Resistance, Viral genetics, HIV Infections drug therapy, HIV-1 drug effects, HIV-1 genetics, Raltegravir Potassium pharmacology, Raltegravir Potassium therapeutic use, Viral Load drug effects

Abstract

Background: Emergence of resistance against integrase inhibitor raltegravir in human immunodeficiency virus type 1 (HIV-1) patients is generally associated with selection of one of three signature mutations: Y143C/R, Q148K/H/R or N155H, representing three distinct resistance pathways. The mechanisms that drive selection of a specific pathway are still poorly understood. We investigated the impact of the HIV-1 genetic background and population dynamics on the emergence of raltegravir resistance. Using deep sequencing we analyzed the integrase coding sequence (CDS) in longitudinal samples from five patients who initiated raltegravir plus optimized background therapy at viral loads > 5000 copies/ml. To investigate the role of the HIV-1 genetic background we created recombinant viruses containing the viral integrase coding region from pre-raltegravir samples from two patients in whom raltegravir resistance developed through different pathways. The in vitro selections performed with these recombinant viruses were designed to mimic natural population bottlenecks., Results: Deep sequencing analysis of the viral integrase CDS revealed that the virological response to raltegravir containing therapy inversely correlated with the relative amount of unique sequence variants that emerged suggesting diversifying selection during drug pressure. In 4/5 patients multiple signature mutations representing different resistance pathways were observed. Interestingly, the resistant population can consist of a single resistant variant that completely dominates the population but also of multiple variants from different resistance pathways that coexist in the viral population. We also found evidence for increased diversification after stronger bottlenecks. In vitro selections with low viral titers, mimicking population bottlenecks, revealed that both recombinant viruses and HXB2 reference virus were able to select mutations from different resistance pathways, although typically only one resistance pathway emerged in each individual culture., Conclusions: The generation of a specific raltegravir resistant variant is not predisposed in the genetic background of the viral integrase CDS. Typically, in the early phases of therapy failure the sequence space is explored and multiple resistance pathways emerge and then compete for dominance which frequently results in a switch of the dominant population over time towards the fittest variant or even multiple variants of similar fitness that can coexist in the viral population.

Published

2018

2. Modulation of HIV-1 Gag NC/p1 cleavage efficiency affects protease inhibitor resistance and viral replicative capacity.

Author

van Maarseveen NM, Andersson D, Lepšík M, Fun A, Schipper PJ, de Jong D, Boucher CA, and Nijhuis M

Subjects

Amino Acid Substitution, DNA Mutational Analysis, HIV-1 drug effects, HIV-1 enzymology, HIV-1 genetics, Humans, Mutant Proteins genetics, Mutant Proteins metabolism, Mutation, Missense, Proteolysis, gag Gene Products, Human Immunodeficiency Virus genetics, Drug Resistance, Viral, HIV Protease metabolism, HIV Protease Inhibitors pharmacology, HIV-1 physiology, Virus Replication, gag Gene Products, Human Immunodeficiency Virus metabolism

Abstract

Background: Mutations in the substrate of HIV-1 protease, especially changes in the NC/p1 cleavage site, can directly contribute to protease inhibitor (PI) resistance and also compensate for defects in viral replicative capacity (RC) due to a drug resistant protease. These NC/p1 changes are known to enhance processing of the Gag protein. To investigate the capacity of HIV-1 to modulate Gag cleavage and its consequences for PI resistance and RC, we performed a detailed enzymatic and virological analysis using a set of PI resistant NC/p1 variants (HXB2431V, HXB2436E+437T, HXB2437T and HXB2437V)., Results: Here, we demonstrate that single NC/p1 mutants, which displayed only a slight increase in PI resistance did not show an obvious change in RC. In contrast, the double NC/p1 mutant, which displayed a clear increase in processing efficiency and PI resistance, demonstrated a clear reduction in RC. Cleavage analysis showed that a tridecameric NC/p1 peptide representing the double NC/p1 mutant was cleaved in two specific ways instead of one.The observed decrease in RC for the double NC/p1 mutant (HXB2436E+437T) could (partially) be restored by either reversion of the 436E change or by acquisition of additional changes in the NC/p1 cleavage site at codon 435 or 438 as was revealed during in vitro evolution experiments. These changes not only restored RC but also reduced PI resistance levels. Furthermore these changes normalized Gag processing efficiency and obstructed the novel secondary cleavage site observed for the double NC/p1 mutant., Conclusions: The results of this study clearly demonstrate that HIV-1 can modulate Gag processing and thereby PI resistance. Distinct increases in Gag cleavage and PI resistance result in a reduced RC that can only be restored by amino acid changes in NC/p1 which reduce Gag processing to an optimal rate.

Published

2012

3. HIV-1 protease inhibitor mutations affect the development of HIV-1 resistance to the maturation inhibitor bevirimat.

Author

Fun A, van Maarseveen NM, Pokorná J, Maas RE, Schipper PJ, Konvalinka J, and Nijhuis M

Subjects

Cell Line, HIV Infections drug therapy, HIV Infections virology, HIV Protease metabolism, HIV-1 drug effects, HIV-1 genetics, Humans, Virus Replication drug effects, gag Gene Products, Human Immunodeficiency Virus metabolism, Drug Resistance, Viral, HIV Protease genetics, HIV Protease Inhibitors pharmacology, HIV-1 physiology, Mutation, Succinates pharmacology, Triterpenes pharmacology, Virus Assembly drug effects, gag Gene Products, Human Immunodeficiency Virus genetics

Abstract

Background: Maturation inhibitors are an experimental class of antiretrovirals that inhibit Human Immunodeficiency Virus (HIV) particle maturation, the structural rearrangement required to form infectious virus particles. This rearrangement is triggered by the ordered cleavage of the precursor Gag polyproteins into their functional counterparts by the viral enzyme protease. In contrast to protease inhibitors, maturation inhibitors impede particle maturation by targeting the substrate of protease (Gag) instead of the protease enzyme itself. Direct cross-resistance between protease and maturation inhibitors may seem unlikely, but the co-evolution of protease and its substrate, Gag, during protease inhibitor therapy, could potentially affect future maturation inhibitor therapy. Previous studies showed that there might also be an effect of protease inhibitor resistance mutations on the development of maturation inhibitor resistance, but the exact mechanism remains unclear. We used wild-type and protease inhibitor resistant viruses to determine the impact of protease inhibitor resistance mutations on the development of maturation inhibitor resistance., Results: Our resistance selection studies demonstrated that the resistance profiles for the maturation inhibitor bevirimat are more diverse for viruses with a mutated protease compared to viruses with a wild-type protease. Viral replication did not appear to be a major factor during emergence of bevirimat resistance. In all in vitro selections, one of four mutations was selected: Gag V362I, A364V, S368N or V370A. The impact of these mutations on maturation inhibitor resistance and viral replication was analyzed in different protease backgrounds. The data suggest that the protease background affects development of HIV-1 resistance to bevirimat and the replication profiles of bevirimat-selected HIV-1. The protease-dependent bevirimat resistance and replication levels can be explained by differences in CA/p2 cleavage processing by the different proteases., Conclusions: These findings highlight the complicated interactions between the viral protease and its substrate. By providing a better understanding of these interactions, we aim to help guide the development of second generation maturation inhibitors.

Published

2011